Method of promoting tissue adhesion

ABSTRACT

The present invention provides methods and devices for promoting tissue adhesion, which utilizes the healing process and scar tissue formation to bond two tissue surfaces together. A tissue injury is accomplished by destroying the mucosal layer of tissue. After the injury is initiated, the tissue is preferably held in close contact by a tissue apposition means such as a suture, staple or clip device placed adjacent to the treatment site. The tissue injury may be initiated by electrical/radiofrequency energy; chemical or mechanical means integrated with the tissue apposition device or delivered by a separate instrument such as an electrocautery catheter through an endoscope. As scar tissue created by the injury forms, the tissue surfaces become bonded together in a permanent union.

RELATED APPLICATIONS

This Application is a divisional of U.S. application Ser. No. 10/275,521, which is the U.S. National Stage of International Application No. PCT/US01/40766, filed on May 18, 2001, which claims the benefit of U.S. Provisional Application No. 60/205,742, filed on May 19, 2000, with each application herein incorporated by reference in its entirety.

FIELD OF THE INVENTION

The present invention relates to methods of treating tissue of the human body, specifically, methods of promoting adhesion between tissue surfaces.

BACKGROUND OF THE INVENTION

Securely joining one tissue portion to another is important to the successful treatment of various medical ailments. However, because tissue is soft, pliable, and moist and is often subject to dynamic movement, it can be difficult to maintain different segments of tissue joined together. Common methods for joining tissue segments together include: suturing with surgical thread secured by a surgical knot, lock device or application of surgical staples. The success of knotted sutures is dependent on the skill of the physician forming a strong surgical knot. Both stapling and suturing are susceptible to failure if the tissue surrounding the suture or staple tears permitting the material to break free and release the tissue.

Another method for retaining segments of tissue together involves the application of adhesive. Adhesives may be applied in connection with a reinforcing substrate that is flexible, such as a bandage or flexible strip. Alternatively, the adhesive may be applied directly to the tissue folds. Biologically safe tissue adhesives are sometimes used in surgical applications to help maintain tissues joined together. However, the moist pliable nature of tissue makes successfully bonding tissue surfaces together difficult. The bonding agent may not adhere to the tissue surface in the presence of biological fluids, etc. Additionally, the dynamic environments in which most tissue areas exist tend to weaken bonds created by adhesives.

Adhering tissue layers together can be challenging in both external treatment sites as well as internal treatment locations. Internally located tissues may be more difficult to bond together because they are more remote and difficult to reach for securement methods, such as suture placement and knot tying. Additionally, internal treatment sites may be exposed to a moist environment of body fluids such as blood or harsh corrosive substances contained within the body that may serve to weaken adhesive bonds or restraining means such as suture or staples.

Joining tissue can be especially challenging in endoscopic tissue apposition procedures. Endoscopic tissue apposition devices are available that can be used in the body of a patient without the need to make an external incision in the patient, the device being controlled externally of the patient by endoscopic means. The device may comprise a sewing or stapling device for use in flexible endoscopy, though it is also applicable to devices for use in rigid endoscopy.

Apposition devices of this general type are described in, for example, U.S. Pat. Nos. 5,080,663 and 5,792,153. Those patents disclose a sewing device for passing a suture thread through a tissue fold, which comprises a hollow needle movable between a first position in which it is out of the said tissue fold and a second position in which it passes through the said tissue fold, and a thread carrier adapted to be attached to the thread and being receivable within the hollow needle. The sewing device comprises a body, which defines a cavity within which the tissue fold can be held by means of suction, and the hollow needle is mounted for movement in the body between the first and second positions.

Two particular embodiments are described in the above-referenced U.S. Pat. No. 5,792,153 patent: a single stitch sewing device, and a multiple stitch sewing device. In the single stitch device, the thread carrier is transported by the needle through the tissue as the latter passes from its first position to its second position. When the needle returns to its first position, the thread carrier is left behind in the distal end of the sewing capsule. In the multiple stitch device, the same procedure occurs, but it is followed by a further step in which the hollow needle travels from its first position to its second position, picks up the thread carrier, and returns it. A second stitch may be formed during the next step. The whole sequence of steps is repeated as many times as may be required to form the desired number of stitches.

A variable in the success of keeping tissue joined together is the quality of the surgical knot tied to secure the tissue. It would be desirable to improve the reliability of the suture knot to increase the level of confidence in the procedures performed using the above-mentioned endoscopic devices. To improve the reliability of known methods of securing tissue together, the methods should be improved, or safeguarded with a secondary securement operation. The present invention provides improved methods and devices for joining tissue.

SUMMARY OF THE INVENTION

The present invention provides a method of promoting tissue adhesion between surfaces of tissue. The method comprises injuring an area of the outer surface layer of each tissue surface that is to be joined in order to initiate an injury response resulting in and the formation of scar tissue. After tissue is injured, it undergoes a healing process, a component of which is the formation of scar tissue. The injured tissue surfaces are held in contact during the healing process and new scar tissue formation occurs between the closely held tissue surfaces, causing the surfaces to grow together as one tissue mass. The resulting tissue mass bonds together the previously separate tissue surfaces. The new tissue growth is commonly shared between the two surfaces. After formation of the new tissue, the tissue will remain together without the aid of external tissue apposition means such as a suture, staple or adhesive.

The tissue surfaces may be held in contact during the healing process and scar tissue formation by a variety of mechanisms. Sutures or surgical staples may be used to hold the tissue in contact during the new tissue formation. Suture material may be secured by a surgical knot or by suture lock configured to frictionally engage the suture threads to prevent relative movement between them and the captured tissue. Examples of such suture locks are presented in international application PCT/US01/07349, filed by the assignee of the present invention. That application is incorporated by reference herein in its entirety. Among suture locks disclosed in that application are a two-part ring and plug combination in which the plug is secured into the ring by a friction fit capturing the suture leads between the mating surfaces to secure them. It is preferred that the tissue apposition mechanism, such as a suture or staple, not pass directly through the tissue at the injured areas. The injured tissue areas have been weakened and may be prone to tearing at the site of the suture or staple. The suture or staple should be placed at an area that is adjacent to the injured tissue area, yet situated so that securement of the staple or suture will result in bringing injured areas of tissue into contact.

The injured tissue surfaces need only be held in contact temporarily, during the healing process, until scar tissue has grown between the injured tissue areas. Therefore, the tissue apposition devices need only be temporary. Bioabsorbable sutures, suture clips, staples or other fastening mechanisms may be used in conjunction with this method. Alternatively, other temporary means for joining tissue may be used such as tissue adhesive.

The injury to the tissue surface need only be slight, sufficient to initiate an injury response and the growth of scar tissue. Accordingly, only the outermost surface of the tissue generally should be abraded or destroyed to promote a healing response and tissue adhesion. Such a controlled injury is preferably created by electrical abrasion means such as application of radiofrequency energy to the intended injury location. Radiofrequency energy may be delivered by a variety of available medical devices designed for application of such energy, for example electrophysiology catheters. In the case of internal tissue treatments an electrocautery catheter could be used.

Alternatively, the tissue abrasion means may be integrated in the tissue apposition device that is used to initially capture and secure the tissue folds together. In particular, the abrasion means, such as RF energy emitting plates may be placed on the surfaces of the apposition device that come into contact with the captured tissue folds intended to be joined together. By applying abrasion energy to the surfaces of the tissue, while it is captured and secured by secondary means such as suture or staples, greater accuracy in locating the abrasion area on the tissue so that it will be properly aligned with the abrasion means on the subsequent tissue mounds. Devices and methods directed to the integrated tissue apposition device and abrasion means are disclosed in PCT/US01/06835, also assigned to the assignee of the present invention. That application is incorporated by reference herein, in its entirety. Additional configurations of the tissue apposition device with abrasion means are also disclosed in detail below.

Alternatively, chemical means for abrading the tissue may be used to create the injury. For example, acids or abrasive substances, such as sodium oleate may provide sufficient abrasion to the tissue surfaces to initiate an injury response that will lead to common growth of new tissue between the tissue surfaces. Alternatively, a chemically abrasive substance may be applied in addition to the radiofrequency treatment to enhance the injury created to insure that a healing response is initiated in the tissue. Mechanical means may also be used to abrade the tissue sufficiently to create an injury response. To initiate a mechanical injury, an abrasive surface may be rubbed against the intended injury areas to injure the tissue. The chemical or mechanical abrasion means also may be incorporated directly into the tissue apposition device or applied separately by an independent instrument.

The present method of promoting tissue adhesion is believed to be especially useful in joining together folds or portions of gastric tissue in an endoscopic tissue apposition procedure to treat gastroesophageal reflux disease (G.E.R.D.). U.S. Pat. Nos. 4,841,888, 5,037,021, 5,080,663 and 5,792,153 describe methods and devices for performing endoscopic suturing of tissue to treat G.E.R.D., all of which are herein incorporated by reference in their entirety. Those patents describe endoscopic suturing devices delivered at the distal end of an endoscope through the esophagus to the area slightly below the gastroesophageal junction, the “Z-line” between the esophagus and the stomach where plications of the gastric tissue are to be formed and secured together by sutures or staples.

A potential problem with this procedure is subsequent release of the sutures from the tissue for a variety of reasons. Over time, the suture may tear through the tissue or may loosen if an improper surgical knot had been tied to secure it. Promoting a tissue adhesion between the folds of tissue by the present method helps to insure a permanent bond between the tissue surfaces, regardless of the condition of the suture after a period of time. The present method is useful to help promote tissue adhesion during endoscopic suturing by creating a tissue injury on the tissue surface between the collected folds of tissue. The tissue injury may be applied prior to or after tightening of the suture to bring the folds in close contact.

Although the present invention is especially useful in the above-described G.E.R.D. treatment, other treatments may benefit from application of the method of the present invention. For example, the method may be used to aid in attaching a feeding tube to the small intestine; enclosing intestinal openings in the case of a fistula, repairing esophageal tears or suturing tissue sites of localized bleeding.

It is an object of the present invention to provide a method of promoting tissue adhesion that utilizes localized tissue injury to initiate a healing response and scar tissue formation to bond tissue surfaces together.

It is another object of the invention to provide a method in promoting tissue adhesion to hold folds of tissue on the gastric surface of the stomach to treat G.E.R.D.

It is another object of the invention to provide a method in promoting tissue adhesion that may be accomplished endoscopically at a remote internal treatment site.

It is another object of the present invention to provide a method of promoting tissue adhesion that uses radiofrequency energy to injure the tissue in order to initiate a healing response that promotes new tissue growth between adjacent tissue surfaces that are held in contact by a tissue apposition mechanism.

It is another object of the invention to provide a tissue apposition device with integrated tissue abrasion means.

It is another object of the invention to provide a method of joining tissue folds together using a tissue apposition device with integrated tissue abrasion means to abrade the tissue that is to be joined.

BRIEF DESCRIPTION OF THE DRAWINGS

The foregoing and other objects and advantages of the invention will be appreciated more fully from the following further description thereof, with reference to the accompanying diagrammatic drawings wherein:

FIG. 1 is a diagrammatic illustration of the region of the gastroesophageal junction between the esophagus and the stomach;

FIG. 2 is a diagrammatic illustration of a distal end of an endoscope;

FIGS. 3-5 are partial sectional side views of a prior art endoscopic tissue apposition device placing a suture through a fold of tissue;

FIG. 6 is a diagrammatic illustration of radiofrequency energy being delivered to injure an area of tissue between two folds of tissue by the use of an endoscopically introduced electrocautery catheter;

FIG. 7 is a diagrammatic illustration of two folds of tissue being secured together after creation of tissue injury area therebetween;

FIG. 8 is a diagrammatic illustration of radiofrequency energy being delivered to injure an area of tissue between two folds of tissue by the use of an endoscopically introduced electrocautery catheter;

FIG. 9 is a diagrammatic illustration of radiofrequency energy being delivered to injure an area of tissue between two folds of tissue by the use of an endoscopically introduced electrocautery catheter; and

FIG. 10 is a diagrammatic illustration of radiofrequency energy being applied to create an injured area of tissue between two folds of tissue that have been tightly secured together in contact by a previously placed suture.

FIGS. 11-13 are partial sectional side views of an endoscopic tissue apposition device placing a suture through a fold of tissue;

FIG. 11A is a sectional view of the endoscopic tissue apposition device of FIG. 11 taken along the line 11A-11A.

FIG. 14 is a diagrammatic illustration of the region of the gastroesophageal junction between the esophagus and the stomach with an endoscopic tissue apposition device placing sutures through folds of tissue;

FIG. 15 is a diagrammatic illustration two folds of tissue having opposing injured tissue surfaces that will be brought into contact by the tightening of the sutures.

DESCRIPTION OF THE ILLUSTRATIVE EMBODIMENTS

The present invention provides a method for promoting tissue adhesion between separate tissue surfaces. As mentioned above, the method is useful for external or internal tissue regions but may be especially useful in endoscopic procedures such as the endoscopic suturing of gastric tissue to treat G.E.R.D. U.S. Pat. Nos. 4,841,888, 5,037,021, 5,080,663 and 5,792,153 describe an endoscopic suturing system and methods with which the present invention is useful or may be used. Those patents are incorporated by reference herein, in their entirety. A brief description of the basic elements of that procedure is presented below and the description of the illustrative embodiment will focus on the method of the present invention as it is used in the endoscopic G.E.R.D. treatment procedure.

FIG. 1 shows a diagrammatic illustration of the gastroesophageal junction (Z-line) 1 between the esophagus 2 and stomach 4, located below the diaphragm 5. Below the junction, a series of placations 8 are formed, each created by joining together two folds or portions 7 of tissue. The folds 7 of tissue are gathered and joined together by a suturing device 52 mounted at the distal end of an endoscope 20, rather than surgically, to reduce treatment time and trauma to the patient.

FIG. 2 shows the distal end 18 of a flexible endoscope 20 with which the present invention may be used. Terminating at a distal face 16 of the endoscope are several channels through which various functions may be performed. Typically, at least one large working channel lumen 14 is provided through which various medical instruments, catheters or accessory control mechanisms may be passed. In the case of viewing endoscopes, a viewing lens 12 is provided on the distal face of the endoscope to permit viewing via optical fiber or digital electronics that extend from the lens to the endoscope to its proximal end. Lights 13 illuminate the treatment site so that it may be viewed through the lens 12. Some endoscopes also have a fluid port 15 through which solution may be passed under pressure to rinse the lens of biological debris during a procedure.

FIGS. 3-5 depict a prior art endoscopic tissue apposition device disclosed in U.S. Pat. No. 5,792,153. FIG. 3 shows the distal end of a flexible endoscope 20, on which a sewing device 52 is attached. As mentioned above, the endoscope is provided with a viewing channel, which is not shown, but which terminates at a lens 12 on the distal face of the endoscope. The endoscope is further provided with a biopsy/working channel 14, and a suction channel 24, the proximal end of which is connected to a source of reduced pressure (not shown). The sewing device 52 has a tube 25, which communicates with the suction pipe 24 and has a plurality of perforations 26 therein. These perforations communicate with an upwardly open cavity 27 formed in the sewing device.

A hollow needle 28 is mounted in the biopsy channel 14, with its beveled tip extending into the sewing device. The needle has a channel 29 extending therethrough. A flexible, wire-wound cable 30 has its forward end attached to the rear of the needle 28, and a center wire 31 runs within the cable 30, along the entire length thereof, and is longitudinally movable with respect thereto. The diameter of the wire 31 is such that it is longitudinally movable within the channel 29 and, in the position shown in FIG. 3, the forward end portion of the wire 31 extends into the rear end portion of the channel 29.

A thread carrier in the form of a tag 32 is mounted in the channel 29. The tag is shown in more detail in the enlarged view, which forms part of FIG. 3. The tag may be hollow and has an aperture 33 extending through the sidewall thereof. As can also be seen in FIG. 3, one end of a thread 34 is secured to the tag by passing it through the aperture 33 and tying in the end of a knot 35 of sufficient size to prevent the thread escaping from the tag.

The sewing device has a hollow head portion 36 defining a chamber 40 therein, with the head portion 36 and the endoscope 1 being on opposite sides of the cavity 27. Between the chamber 40 and the cavity 47 is a wall 37, in which there is formed an aperture 58. The aperture 38 has a diameter that is marginally greater than the external diameter of the needle 28, and is aligned therewith. The clearance between the needle 28 and the aperture 38 must be sufficiently small to prevent tissue from being forced through the aperture and causing the needle to jam. Finally, FIG. 3 shows a portion of the patient's tissue 39, in which a stitch is to be formed.

In operation, suction is applied to the suction pipe 24, and thence, via the perforations 26 in the tube 25 to the cavity 27. This sucks into the cavity a U-shaped fold 7 of the tissue 39, as shown in FIG. 4. The hollow needle 28 is pushed through the U-shaped tissue fold 7 by exerting a distal (leftward) force on the wire-wound cable 30, and the tag 32 is pushed along the channel 29 from right to left, by exerting a leftwards force on the center wire 31. After full advancement of the needle, the tip portion of the needle 28 is on the left-hand side of the wall 37, within the chamber 40 in the hollow head portion 36, and the tag 32, within the channel 29, lies to the left of the wall 37.

Continued distal movement of the wire 31 pushes the tag 32 out of the channel 29 and into the chamber 40. The wire 31 is then withdrawn proximally (rightwardly), followed by the proximal withdrawal of the cable 20, to bring both back to the positions which they occupy in FIG. 3. The suction is then discontinued so allowing the U-shaped tissue fold 7 to be released from the cavity 27. The position is then as shown in FIG. 5. Finally, the endoscope and sewing device are withdrawn from the patient. In so doing, the thread 34 is pulled partially through the tissue fold 7, since the tag 32 is trapped in the chamber 40. The end result is that both ends of the thread are outside of the patient and can be knotted and/or severed as may be appropriate. It should be noted that a multiple stitch embodiment also is disclosed in U.S. Pat. No. 5,792,153.

FIG. 6 is a diagrammatic illustration of an injury area 50 being created between two folds 7 of tissue that have been captured and penetrated by a suture 34. In a preferred method, after a suture has been placed through the two folds 7, the first endoscope 20, equipped with the suturing system 52, is withdrawn from the esophagus of the patient. Next, a second endoscope 58, without an endoscopic suturing accessory, is then navigated through the esophagus to the Z-line region 1 and site of the tissue folds 7 and suture 34. An electrocautery catheter 60 is introduced through the working channel lumen of the endoscope 58 and, after protruding from the distal end 68 of the endoscope, is directed to the area of tissue between the two folds 7. The second endoscope 58 can be a distal viewing endoscope as shown in the figures, or it may be a side viewing type endoscope (not shown) having a side facing distal working channel port through which an electrocautery catheter would exit.

A standard, commercially available electrocautery catheter is suitable for creating the desired injury, such as the Bard Bi-Polar Hemostasis Probe connected externally to a Valley Lab electrosurgical generator available from Bard Interventional Products Division, C. R. Bard Inc., 129 Concord Road, Billerica, Mass. 01821, or a Gold Probe, bicap probe using an Endostat II generator available from the Microvasive Division of Boston Scientific Corporation, 480 Pleasant Street, Watertown, Mass. 02172. Because a bi-polar type electrocautery probe delivers energy only to a shallow depth of tissue, it is preferred for creating the desired tissue injury of only the outer-most tissue layer or mucosal layer. A mono-polar type probe would not be as suitable for creating the desired shallow injury because it delivers destructive energy more deeply below the tissue surface. The energy applicator at the distal tip of the catheter is directed to the appropriate tissue site by viewing the catheter movement through the endoscope. Directional control of the catheter is accomplished by controlling the distal tip 68 of the endoscope. Additionally, an electrocautery catheter may have a precurved distal tip to aid in navigation after it exits the endoscope. Additionally, a side viewing endoscope offers further directional control over a catheter exiting through the distal port of its working channel by the operation of a movable elevator to affect lifting and angling of the catheter shaft as it exits the endoscope.

As mentioned above, the tissue injury area 50 is preferably positioned between the two tissue folds 7. The area between the folds 7 forms a U-shaped trough 70 when the folds are partially gathered and brought together. Preferably, injury is produced along the bottom of the trough 72, extending partially up the opposing surfaces 86 and 88 on the sides 74 of the trough. However, the injury area 50 should not be extended to include the suture penetration points 78 of the tissue. Creation of the tissue injury by destruction of the mucosal layer weakens the tissue. Tissue that has been injured and contains a suture would be more susceptible to tearing under the motion and concentrated stress of the suture at the penetration points 78.

The injury created by the electrocautery catheter should only affect the mucosal layer of the gastric tissue and should be of a magnitude sufficient to initiate an injury response in the tissue to promote scar tissue growth. Using radiofrequency electrocautery, with a bi-polar probe, it has been found that the desired injury level can be achieved by applying bicap cautery in an approximate range of 25 to 50 watts for an approximate time period of between 2 to 6 seconds.

Alternatively or supplementally, chemical abrasion means may be used to cause injury area on the surface of the tissue. Abrasive or corrosive substances such as sodium oleate may be applied to the desired injury area to chemically abrade the mucosal layer of tissue. Alternatively, the chemical substance may be applied after application of the radio frequency energy to help initiate a tissue injury response that will lead to scar tissue formation between the opposing tissue surfaces 86 and 88.

Alternatively, a mechanical element may be used to abrade the tissue to initiate an injury response on the tissue surface between the tissue folds 7. The mechanical means may comprise an abrasive surface at the distal end of a catheter that is rubbed against the surface of the tissue to create an abrasion that will lead to an injury response and scar tissue formation. New scar tissue will form in the injured tissue area 50, which will unite the two opposing tissue surfaces 86 and 88 as one tissue mass once the healing process has become advanced.

As shown in FIG. 7 after the tissue injury area 50 has been created, suture 34 may be tightened to draw together the tissue folds 7 and the injured tissue of opposing surfaces 86 and 88 that were created at the bottom 72 and sides 74 of the trough 70. The opposing tissue surfaces 86 and 88 of each tissue fold are thus drawn into contact by the tightening of the suture 34. The suture is then secured by a securement mechanism such as several surgical knots 90. Surgical knots may be run down to the suture site by a knot pusher device attached to the distal end of an endoscope as described in U.S. Pat. No. 6,010,515. Alternatively, the suture may be secured by a suture lock device, such as that described in U.S. Pat. No. 5,584,861. The tissue may also be secured by a staple device such as disclosed in U.S. Pat. No. 5,037,021. The above referenced patents are incorporated by reference herein in their entirety.

As shown in FIGS. 8 and 9, after the opposing surfaces 86 and 88 located at the bottom 72 and sides 74 of the trough 70 has been abraded, opposing surfaces 92 and 94 at the top 96 of the trough 70, above the suture penetration points 78, may be abraded to provide additional tissue adherence between the tissue surfaces.

Another preferred method of promoting tissue adhesion between two folds 7 of tissue is shown in FIG. 10. In this method, the suture 34 is tightened to bring the opposing surfaces 86 and 88 and 92 and 94 of the folds 7 into contact before the tissue injury area 50 is created by the electrocautery catheter 60. After the suture 34 is tightened, the electrocautery catheter 60 is navigated to become wedged between the tissue folds 7 in the trough 70. Once residing in the trough, radio frequency energy is applied to the surrounding tissue surfaces of the bottom 72 and the sides 74 of the trough.

It should be noted that FIG. 10 shows the trough to be a size that permits free access of the distal end 100 of the electrocautery catheter 60 for illustration purposes only. The actual size of the trough 70 after the suture 34 has been pulled tight to secure the tissue folds 7 would be very small or almost non-existent, with opposing surfaces 86 and 88 in contact. However, due to the pliable nature of the tissue, the catheter can still be negotiated between the folds 7 to apply energy to the trough region. An advantage of applying the injury inducing energy after the suture 34 has been tightened is that the surfaces that should be subjected to injury to become bonded will have been clearly defined to the treating physician. Additionally, the snug fit of the catheter in the reduced size trough 70 will insure that the catheter position is correct to deliver its injury creating energy.

In another aspect of the invention, abrasion means are integrated into the tissue apposition device so that abrasions may be created on the tissue while it is captured by the apposition device 52. A modified tissue apposition device is shown in FIGS. 11-13. The tissue apposition device is modified by the incorporation of tissue abrasion means 102 on at least one tissue contacting surface of the device. The placement of the abrasion means on the apposition device is partially dictated by technical limitations: where the means can be fit onto the device while remaining operable from the proximal end by a user. However, placement of the abrasion means should also be dictated by the desired final arrangement of joined tissue surfaces and the orientation that the apposition device will have relative to that arrangement when it is advanced to the subject area. The abrasion means should be arranged on the device so that injury may be applied to opposing tissue surfaces on the tissue folds that are to be brought together. The injury should be applied to the two tissue surfaces that will be brought into contact with each other. In the example shown in FIGS. 11-13, an abrasion means is located on the sidewalls 104 of the cavity 27 of the apposition device 52. That orientation is suitable for the plication formation described below in connection with FIGS. 14 and 15. However, the abrasion means may be located in various other locations on the apposition device to accommodate a different orientation of the device that may be required to reach a different area of the body or to create a different arrangement of plications. Another consideration in placement of the abrasion means is avoidance of the tissue securement device pathway, such as the needle and suture path through the tissue in the present example. As mentioned above, the suture should not penetrate the area of tissue injury because it is weak and subject to tearing. Placing the abrasion means 102 on the sidewalls 104 of the capsule serves to create injury on the sides of the tissue fold 7 rather than along the suture path, which extends front to back (proximal to distal). Abrasion means may be applied anywhere on the apposition device, on the outside surface or within the cavity 27.

The abrasion means may comprise any of the mechanisms described above: electrical (RF), chemical or mechanical. In FIGS. 11-13 the abrasion means comprises an RF energy emitting plate 102 secured to the sidewall 104 of the suction cavity 27 by such means as adhesive or mechanical fasteners. The RF plate is energized by a wire 106 that extends from the plate, proximally along the endoscope 20 to a RF generator located external to the patient. The wire 106 may extend along the exterior of the scope, with the vacuum tube 24. The penetration point of the wire into the cavity 27 may be sealed to maintain strong suction in the cavity when vacuum is applied.

Because the RF plate 102 conducts electrical energy, it must be insulated from other metal components of the system. The RF plates may be formed from stainless steel and may be coated with a material of greater conductivity such as gold or copper. To prevent electrical conducting to other metal components of the tissue apposition device, the capsule 52 may be formed of a non-conductive material, such as a rigid polymer. Alternatively, the surfaces of the capsule may be insulated from the exposed metal RF plate 102 by coating or lining the surfaces with Teflon or other known insulator materials.

As shown in the sectional view of FIG. 11A, taken along the line 11A-11A of FIG. 11, left and right RF plates 112 and 114 may be provided for left and right sidewalls 116 and 118. The sectional view shows the capsule from the distal end of the scope looking forward, therefore left and right are defined in this discussion from that perspective. The RF plates 112 and 114 are positioned to abrade both sides of a tissue fold 7, but preferably the left and right plates are independently operable so that just one side of the tissue fold can selectively be abraded. The selective abrasion capability increases the flexibility of how plications may be arranged and secured together.

In operation of the apposition device with abrasion means, shown in FIGS. 11-13, suction is applied to the suction pipe 24 and cavity 27, via the perforations 26 in the tube 25 to aspirate a U-shaped fold 7 of the tissue 39 into the cavity, as shown in FIG. 12. The hollow needle 28 is pushed through the U-shaped tissue fold 7 by exerting a distal (leftward) force on the wire-wound cable 30, and the tag 32 is pushed along the channel 29 from right to left, by exerting a leftwards force on the center wire 31. After full advancement of the needle, the tissue is secured in the cavity and will not move appreciably even if it escapes the suction force applied through the cavity 7. In this secured position, the abrasion energy may be applied to cause a tissue injury to the surfaces of the tissue in contact with the RF plates 102. To abrade the tissue, electrical (RF) energy may be applied form the proximal end of the endoscope through the wire 106 to energize the plates 102. Selective activation of the energy between the left and right plates 112 and 114 may be provided. RF energy parameters and times are the same as for the independent RF devices described above.

After application of the abrasion energy the application of the tissue securement mechanism, such as a suture may proceed as was described above for the prior art device in FIGS. 3-5. Continued distal movement of the wire 31 pushes the tag 32 out of the channel 29 and into the chamber 40. The wire 31 is then withdrawn proximally (rightwardly), followed by the proximal withdrawal of the cable 20, to bring both back to the positions which they occupy in FIG. 11. The suction is then discontinued, allowing the U-shaped tissue fold 7 to be released from the cavity 27. As shown in FIG. 13, the resulting tissue fold 7 has an injury area 120 where the abrasion energy was applied. The injury area 120 reflects application of abrasion energy having been applied by right RF plate 114, which cannot be shown in the sectional views of FIGS. 11-13. Likewise, an injury area on the opposite side of injury 120, produced by left RF plate 112, cannot be seen in FIG. 13.

To form plications, with the endoscopic tissue apposition device having abrasion means, two folds of tissue are brought together by tightening of the suture to form a plication. The injured areas 120 on the tissue folds should be aligned to contact each other when the suture is tightened to draw the folds together to form a plication. The series of plications may be formed in a variety of configurations and the most effective configurations for the treatment of GERD is still a subject of investigation at this time. However, several preferred techniques have been established, including the plication configuration described above in connection with the separately applied abrasion devices.

In another preferred technique shown in FIGS. 14 and 15, tissue folds 7 or folds are captured and sutured at radially spaced locations around the Z-line 1. The tissue capture locations should be at approximately the same longitudinal level. For example the endoscope 20 may be inserted into the esophagus 2 to the proper depth relative to the Z-line for plication formation. The initial insertion depth may be verified visually through the endoscope, and depth placement for subsequent intubations verified visually through the scope or by observation of the endoscope shaft location external to the patient, relative to the mouth.

Next the endoscope is rotated to approximately the one o'clock position and a fold of tissue 130 is captured. Preferably, the needle is advanced through the tissue to hold it in position while abrasion is performed. While the tissue is captured in the cavity, one of the abrasion elements 102 is activated to abrade an area on one side of the tissue fold 130 that will face the next tissue section captured. In FIG. 14, the next tissue fold that will be captured is the 3 o'clock position fold 134. To place an injury 120 on tissue fold 130 that faces fold 134, the left RF plate 112 of the capsule alone should be activated. FIG. 15 shows the injury area 120 on fold 130 in phantom. However, if the apposition device is not configured for independent control of left and right RF plates, both sides of the tissue fold may be abraded. The side of the fold that will not be brought into contact with another fold of tissue will heal without adverse consequence. After the abrasion is created, the suturing procedure may be completed to maintain the tissue fold configuration: the suture is advanced through the needle and tissue fold, needle is withdrawn from the tissue and vacuum is discontinued to release the tissue.

Next, a second tissue fold 134 is captured to be joined to the first tissue fold to form a plication. To capture a second, adjacent fold, the endoscope 20 and suturing capsule 52 may be withdrawn outward from the patient and the suture lead reloaded into the needle for another suture delivery through the second tissue fold located adjacent to the first captured tissue fold. The endoscope is again advanced down the esophagus to a depth equal to that of the first tissue capture. The scope is rotated to the 3 o'clock position to be radially adjacent to the first tissue fold. A tissue fold 134 is aspirated into the cavity 27 and the needle is advanced through the fold to secure it. An abrasion area 120 is created on the side of the tissue fold facing the first tissue fold by activating the right RF plate 114. After the abrasion is created, the suture may be passed through the needle and the tissue fold, needle withdrawn, aspiration discontinued and tissue released. With the two adjacent tissue folds secured by sutures and having facing abrasions, the suture leads 34 may be tightened to draw the tissue folds together with the facing abrasions 120 coming into contact. When the sutures are tightly secured by surgical knot or suture lock. The abrasion areas will be maintained in contact and will heal together, permanently joining the surfaces of the tissue folds. 

1. A method of promoting tissue adhesion between surfaces of tissue, the method comprising: collecting a first tissue area into a first fold, placing a suture through the first fold; releasing the first tissue area; collecting a second tissue area, adjacent to the first tissue area, into a second fold; placing the suture through the second fold; creating a tissue injury between the first and second tissue folds; tightening the suture to draw the first and second tissue folds and the injured tissue into contact with each other; and securing the suture to hold the first and second tissue folds and the injured tissue in contact with each other.
 2. The method as defined in claim 1, wherein the tissue is gastric tissue and the injury is applied to the mucosal layer of the gastric tissue.
 3. The method as defined in claim 2, wherein the method is performed endoscopically.
 4. A method of promoting tissue adhesion between the surfaces of tissue, the method comprising: collecting a first tissue area into a first fold; placing a tissue fastener through the first fold; releasing the first tissue area; collecting a second tissue area, adjacent to the first tissue area, into a second fold; placing the tissue fastener through the second fold; releasing the second tissue area; tightening the tissue fastener to draw the first and second tissue folds together; inserting a tissue injury device between the first and second tissue folds; creating a tissue injury between the first and second tissue folds with the tissue injury device; and securing the tissue fastener to hold the first and second tissue folds together.
 5. The method as defined in claim 4, wherein the tissue is gastric tissue and the injury is applied to the mucosal layer of the gastric tissue.
 6. The method as defined in claim 5, wherein the method is performed endoscopically.
 7. A method of promoting tissue adhesion surfaces of gastric tissue, the method comprising: advancing a first endoscope through the esophagus of a patient to a location adjacent a first area of gastric tissue below the gastroesophageal junction, the first endoscope having an endoscopic suturing device at its distal end; applying vacuum to the suturing device to capture a first tissue fold; passing a suture through the first tissue fold with a needle; withdrawing the needle and releasing the first tissue fold from the suturing device; moving the endoscopic suturing device to a second area of gastric tissue; applying vacuum to capture a second tissue fold; advancing the suture through the second tissue fold with the needle; withdrawing the needle and releasing the second tissue fold; withdrawing the first endoscope from the patient; advancing a second endoscope through the esophagus of the patient to the vicinity of the first and second tissue folds; advancing an electrocautery catheter through the working channel of the second endoscope and beyond the distal end of the second endoscope; applying radiofrequency energy to the gastric tissue surface between the locations of the suture placed through the first and second tissue folds to create an injured tissue area; withdrawing the electrocautery catheter and the second endoscope from the patient; tightening the suture to draw the first and second tissue folds together and place the injured tissue area in contact; and securing the suture to maintain the injured tissue area in contact.
 8. A tissue apposition device comprising: a cavity for capturing a tissue portion; a tissue securement device including a needle adapted to deliver a suture along a suture path to penetrate a tissue portion captured in the cavity; and a tissue abrasion device positioned within the cavity and adapted to produce an area of tissue injury to a captured tissue portion, the tissue abrasion device including one or more RF energy emitting plates configured to create an area of tissue injury to a region of the captured tissue portion that is not penetrated by the needle.
 9. The tissue apposition device as defined in claim 8, wherein the cavity captures tissue by application of vacuum.
 10. The tissue apposition device as defined in claim 8, wherein the tissue abrasion device includes two or more RF energy emitting plates.
 11. The tissue apposition device as defined in claim 10, wherein the RF emitting plates are constructed and arranged with the suture path extending therebetween.
 12. The tissue apposition device as defined in claim 10, wherein the RF emitting plates are independently operable.
 13. The tissue apposition device as defined in claim 10, wherein each RF energy emitting plate forms a tissue-contacting surface within the cavity.
 14. The tissue apposition device as defined in claim 8, wherein the tissue abrasion device further includes a mechanical abrader adapted to abrade tissue.
 15. A method of joining tissue surfaces, the method comprising: providing a tissue apposition device having a tissue securement device, a cavity and a tissue abrasion device; placing the tissue apposition device adjacent a first tissue portion; capturing the first tissue portion in the cavity; advancing the tissue securement device through the first tissue portion; abrading a surface of the first tissue portion with the tissue abrasion device; releasing the first tissue portion from the cavity; moving the tissue apposition device to a second tissue potion; capturing the second tissue portion into the cavity; advancing the tissue securement device through the second tissue portion; abrading a surface of the second tissue portion with the tissue abrasion device; releasing the second tissue portion from the cavity; and tightening the tissue securement device to draw the first and second tissue portions together and place the abraded surfaces in contact. 